Equilibrium Structures of Pyrazine, s-Triazine, and s-Tetrazine

In recent years, accurate equilibrium (re) structures have been determined for pyridine, pyridazine, and pyrimidine. Here, we report accurate re structures for the structurally related molecules pyrazine, s-triazine, and s-tetrazine, which were obtained using a composite approach based on explicitly correlated coupled-cluster theory (CCSD(T)-F12b) in conjunction with a large correlation-consistent basis set (cc-pCVQZ-F12) to take core–valence electron correlation into account. Additional terms were included to correct for the effects of iterative triple excitations (CCSDT), noniterative quadruple excitations (CCSDT(Q)), and scalar relativistic contributions (DKH2-CCSD(T)). The performance of this computational procedure was established through test calculations on selected small molecules. For s-triazine, accurate experimental ground-state rotational constants (B0) of the parent molecule and six D3h isotopologues from the literature were used to determine a semiexperimental re structure, which was found to be essentially identical with the best estimate from the current composite approach. The presently recommended equilibrium structural parameters of s-triazine are re(CH) = 108.17 pm, re(CN) = 133.19 pm, and θe(NCN) = 125.95°, with estimated uncertainties of ±0.10 pm and ±0.10°, respectively. The predicted equilibrium geometries for pyrazine and s-tetrazine are expected to be of the same accuracy. We recommend for pyrazine: re(CH) = 108.16 pm, re(CN) = 133.34 pm, re(CC) = 139.07 pm, θe(CNC) = 115.60°, and θe(HCC) = 120.75°; and for s-tetrazine: re(CH) = 107.95 pm, re(CN) = 133.39 pm, re(NN) = 132.01 pm, and θe(NCN) = 126.59°

Overtones of the Si−H Stretching−Bending Polyad in SiHD₃: Internal Coordinate Force Field, ab initio Dipole Moment Surfaces, and Band Intensities

Overtones of the Si−H stretching−bending polyad of the SiHD3 molecule are studied using an internal coordinate force field model. The potential parameters are optimized by fitting to the experimental band centers. The Fermi resonance between the Si−H stretching and bending motions is insignificant due to cancellation of the contributions from kinetic and potential terms. This suggests a slow redistribution of vibrational energy between these two degrees of freedom and induces local mode character of respective vibrations. Band intensities are calculated by using ab initio one- and three-dimensional dipole moment surfaces (DMS). These agree reasonably well with the observations. The successful reproduction of relative intensities between the (n1 − 1)ʋ1 + 2ʋ5 stretching−bending combination bands and the n1ʋ1 stretching bands establishes the importance of the bending motion in the multidimensional DMS for intensity investigations

Millimeter-Wave Spectra, ab Initio Calculations, and Structures of Fluorophosphane and Chlorophosphane

The structures of fluorophosphane, PH2F, and chlorophosphane, PH2Cl, have been calculated ab initio at the SCF, MP2, CCSD, and CCSD(T) levels using a quadruple ζ polarized basis set. Equilibrium and ground state rotational constants as well as centrifugal distortion constants have been predicted for several isotopomers of PH2F and PH2Cl. Theoretical CCSD(T) geometries were also determined for the series of PHnX3-n (X = F, Cl; n = 0−3) molecules using a triple ζ polarized basis set. The millimeter-wave spectra of the short-lived molecules PH2F, PH2Cl, and their perdeuterated species were measured in the frequency range 100−470 GHz. For PH2F and PH2Cl, accurate ground state parameters have been obtained by a combined fit of the millimeter-wave data and the infrared ground state combination differences. The ro, rz, and re structures of PH2F and PH2Cl, as well as PH3, PCl3, and PHF2 have been determined. The experimental results are found in excellent agreement with their ab initio predictions

The heats of formation of the haloacetylenes XCCY [X, Y = H, F, Cl]: basis set limit ab initio results and thermochemical analysis

The heats of formation of haloacetylenes are evaluated using the recent W1 and W2 ab initio computational thermochemistry methods. These calculations involve CCSD and CCSD(T) coupled cluster methods, basis sets of up to spdfgh quality, extrapolations to the one-particle basis set limit, and contributions of inner-shell correlation, scalar relativistic effects, and (where relevant) first-order spin-orbit coupling. The heats of formation determined using W2 theory are: \hof(HCCH) = 54.48 kcal/mol, \hof(HCCF) = 25.15 kcal/mol, \hof(FCCF) = 1.38 kcal/mol, \hof(HCCCl) = 54.83 kcal/mol, \hof(ClCCCl) = 56.21 kcal/mol, and \hof(FCCCl) = 28.47 kcal/mol. Enthalpies of hydrogenation and destabilization energies relative to acetylene were obtained at the W1 level of theory. So doing we find the following destabilization order for acetylenes: FCCF $>$ ClCCF $>$ HCCF $>$ ClCCCl $>$ HCCCl $>$ HCCH. By a combination of W1 theory and isodesmic reactions, we show that the generally accepted heat of formation of 1,2-dichloroethane should be revised to -31.8$\pm$0.6 kcal/mol, in excellent agreement with a very recent critically evaluated review. The performance of compound thermochemistry schemes such as G2, G3, G3X and CBS-QB3 theories has been analyzed.Comment: Mol. Phys., in press (E. R. Davidson issue

Shadowing in Inelastic Scattering of Muons on Carbon, Calcium and Lead at Low XBj

Nuclear shadowing is observed in the per-nucleon cross-sections of positive muons on carbon, calcium and lead as compared to deuterium. The data were taken by Fermilab experiment E665 using inelastically scattered muons of mean incident momentum 470 GeV/c. Cross-section ratios are presented in the kinematic region 0.0001 < XBj <0.56 and 0.1 < Q**2 < 80 GeVc. The data are consistent with no significant nu or Q**2 dependence at fixed XBj. As XBj decreases, the size of the shadowing effect, as well as its A dependence, are found to approach the corresponding measurements in photoproduction.Comment: 22 pages, incl. 6 figures, to be published in Z. Phys.

Equilibrium Structure and Spectroscopic Constants of Difluorovinylidene: An ab Initio Study

Highly correlated ab initio calculations with large basis sets are reported for difluorovinylidene, F2CC. Based on CCSD(T)/aug-cc-pVQZ results and taking core correlation effects properly into account, a reliable theoretical equilibrium geometry is derived: re(CC) = 134.74(10) pm, re(CF) = 131.00(10) pm, and ∠e(FCC) = 123.23(10)°. The error bars are estimated from analogous comparative calculations on the equilibrium structures of the CF2, C2, and C3 species. Correlated harmonic [CCSD(T)/aug-cc-pVQZ] and anharmonic [CCSD(T)/TZ2Pf] force fields provide theoretical values for the fundamental vibrational wavenumbers which are in excellent agreement with those measured previously in an argon matrix. Many spectroscopic constants of F2CC are predicted. In addition, the energy of F2CC relative to difluoroethyne (FCCF) and the barrier to isomerization from F2CC to FCCF have been reinvestigated by means of the present high-level ab initio calculations

A Systematic Ab Initio Study of the Group V Trihalides MX₃ and Pentahalides MX₅ (M = P—Bi, X = F—I)

Ab initio calculations using effective core potentials and polarized split-valence basis sets are reported for the title compounds. The calculated geometries, vibrational frequencies, infrared intensities, harmonic force fields, dipole moments, relative energies, and barriers to pseudorotation are compared with the available experimental data for the known molecules. Predictions are made for those pentahalides that are still unknown. Trends in the calculated properties are identified and discussed

Theoretical study of the harmonic and anharmonic force fields of phosphorus pentafluoride

The harmonic force field of PF5 is calculated at the ab initio SCF (self-consistent field) level and at the correlated MP2 level (second-order Møller-Plesset perturbation theory) using triple-zeta basis sets with multiple polarization functions (up to f functions at phosphorus). The ab initio results support the validity of a previous harmonic force field which has been refined with respect to experimental data while constraining certain off-diagonal force constants to scaled SCF values. The anharmonic force field of PF5 is obtained from ab initio SCF calculations. The theoretical anharmonic spectroscopic constants agree reasonably well with the experimental data that are available. Many unknown spectroscopic constants are predicted

Anharmonic force field and spectroscopic constants of silene: an ab initio study

High-level ab initio calculations with large basis sets are reported for silene, H2C=SiH2. Correlated harmonic force fields are obtained from coupled cluster CCSD(T) calculations with the cc-pVQZ basis (cc-pVTZ for H) while the anharmonic force fields are computed at the MP2/TZ2Pf level. There is excellent agreement with the available experimental data, in particular the equilibrium geometry and the fundamental vibrational frequencies. Many other spectroscopic constants are predicted for the C2v isotopomers of silene